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Jet nozzlesType DUK
T 1.2/2/EN/2
TROX GmbH Telephone +49/28 45/2 02-0Telefax +49/28 45/2 02-2 65
Heinrich-Trox-Platz e-mail [email protected] Neukirchen-Vluyn www.troxtechnik.com
2
Contents · Description
Description 2Preliminary Selection 3Construction · Dimensions 4Material · Installation 5Installation · Assembly 6Normenclature 7Selection Method 8Aerodynamic Data 9Acoustic Data 11Order Details 12
Jet nozzles are used for preference where the supply air from thediffuser has to travel a large distance to the occupied zone.
This is the case in large rooms (halls, assembly rooms etc.),particularly when the distribution of air via ceiling diffusers is notpossible or not practical. Here jet diffusers are arranged in the side wall areas. When the temperature difference between the supply air and the room air changes, the supply air stream isdeflected upwards (warm air) or downwards (cold air).The direction of the supply air flow is also affected by otherinfluences such as local convection effects or draughts withinthe room.
The direction of the air stream from the type DUK-V jet nozzlecan be easily adjusted manually to suit particular on siteconditions.
Also the pivoting movement can be motorised within the rangeof ± 30°.The electric actuators for this can be externally or internallymounted.
The well-designed, aerodynamically efficient shape of Trox jetnozzles results in low noise characteristics. For this reason, andbecause of the sophisticated design, they can be used in criticalareas such as concert halls, theatres, museums etc.
The wide range of designs available, the flexibility in adapting to local conditions and compliance with low noise requirementsmean that Trox jet nozzles can be used in almost any airconditioning system.
cold air
warm air
3
Preliminary Selection
The table below gives a guide for selecting the size of jetnozzles.The values shown are determined for an isothermal, single freehorizontal air stream. According to our extensive experience, air velocities of 0.25 m/s for example, with a throw of 30 m, areonly possible in theory as many room parameters must be takeninto account with such throw distances.If the supply air temperature difference changes, the air streamdeflection in diagram 2 (page 9) must be taken into account.
The noise levels apply to types DUK-F and DUK-V.For other design variants, corrections must be made.
In the table below no data is given for effective discharge velocities below 2 m/s nor are values given above a sound power level rating of 55 dB(A). If the values required lie outside thelimits of this table the procedures on page 8 should be followed.On our web site www.trox.de we offer an electronic selectionprogramme.
Data for axial air flow, types DUK-F and DUK-VThrow Air
10 m 20 m 30 m VelocitySize
V.
LWA LWNC V.
LWA LWNC V.
LWA LWNC v- L
l/s dB(A) NC l/s dB(A) NC l/s dB(A) NC m/s
...-F ...-V* ...-F ...-V* ...-F ...-V* ...-F ...-V* ...-F ...-V* ...-F ...-V*
100 – – – – – 26 31 29 30 23 39 42 41 41 35
125 – – – – – 34 27 25 26 22 50 37 36 37 30
160 23 �20 �20 �20 �20 46 �20 �20 �20 �20 69 32 35 33 28
200 29 �20 �20 �20 �20 61 �20 �20 �20 �20 85 26 27 25 20 0.25
250 37 �20 �20 �20 �20 76 �20 �20 �20 �20 106 23 22 23 � 20
315 50 �20 �20 �20 �20 98 �20 �20 �20 �20 150 21 20 22 � 20
400 65 �20 �20 �20 �20 129 �20 �20 �20 �20 195 � 20 � 20 21 � 20
100 26 31 29 30 23 52 50 50 49 45 – – – – –
125 34 27 25 26 22 68 46 46 45 40 – – – – –
160 46 �20 �20 �20 �20 92 39 44 40 37 138 50 55 51 49
200 61 �20 �20 �20 �20 121 36 38 35 31 182 47 50 47 44 0.5
250 76 �20 �20 �20 �20 152 32 34 32 26 229 43 45 43 39
315 98 �20 �20 �20 �20 195 27 28 28 20 293 39 40 40 32
400 129 �20 �20 �20 �20 258 27 20 28 � 20 387 37 33 39 26
100 52 50 50 49 45 – – – – – – – – – –
125 68 46 46 45 40 – – – – – – – – – –
160 92 39 44 40 37 – – – – – – – – – –
200 121 36 38 35 31 242 49 – 49 – – – – – – 1.0
250 152 32 34 32 26 305 51 53 51 47 – – – – –
315 195 27 28 28 20 390 47 48 48 41 585 53 – 54 –
400 258 27 20 28 � 20 516 45 42 43 35 773 51 53 53 47
* See p. 11 for corrections for deflection angle
4
Construction · Dimensions
Jet nozzles type DUK are suitable for almost all situationsbecause of the wide range of variants available.Fixed construction type DUK-F consists of a nozzle with fixingholes.Adjustable construction type DUK-V consists of a sphericaldischarge nozzle mounted in a housing and is complete with afront mounting flange and circular spigot for direct connection to a circular duct. The nozzle can be adjusted manually up tomax. 30° in any direction.
The adjustment can also be made with an electric actuator.With an actuator the nozzle can only be rotated in one plane upto 30° upwards (cooling) up to 30° downwards (heating). A rearduct connection element with a peripheral flange and optionalspigot or a saddle connector with flange are available as optionsfor fixing to the side of rectangular or circular ducts.
DUK-V-A-E4…E6 (shown)DUK-V-K-E4…E6DUK-V-R-E4…E6
DUK-V-R-E1…E3
DUK-V-A-E1…E3 (shown)DUK-V-K-E1…E3
L2
øD
4
øD
5
øD
3
E
F
øK øD4
L3*
øD3
øK
øR
L3*
60°
15
øD3
L3*
øK 60°
øD3
øD4
DUK-F
DUK-V
Externally mountedelectric actuator
Externally mountedelectric actuator
Rotary actuator
Rotary actuator
Swivel movement using internallymounted linear electric actuator
Linear electric actuator
Counterpunched hole � 4.5 mmfor raised countersunkself-tappingscrews 4.2 x 16, DIN 7973
Size D1 D2 D3 D4 D5 E F K L1 L 2 L 3*
100 136 115 146 98 50 11 – 3 134 94 87 84
125 159 138 169 123 64 11 3 157 112 96 94
160 225 201 200 158 82 11 9 188 122 105 114
200 265 241 257 198 108 16 9 242 153 126 143
250 315 291 302 248 136 16 21 287 187 162 172
315 400 376 384 313 174 23 23 358 224 196 223
400 485 461 467 398 230 24 45 441 287 201 262
* For constructions with actuators, L3 = 365 mm irrespective of size.
Size Possible Circular Duct Diameters R200 250 315 500 630 800
100 �
125 �
160 � � � �
200 � � �
250 � � �
315 � � �
400 � �
5
DUK-V-KExample of rectangular duct connection
DUK-V-RExample of circular duct connection
DUK-V-AExample of duct or flexible duct connection
Suspensionby others
Materials · Installation
MaterialsThe discharge nozzle and face cover ring are in aluminium (natural finish).The mounting for the eyeball is with two plastic rings colour white RAL 9010. Temperature resistant up to max. 50°C.The duct connection element and saddle connection are ingalvanised sheet steel.The surface can be painted if required, powder coated in white(RAL 9010) or other RAL colours.
InstallationTrox jet nozzles are suitable for mounting on rectangular orcircular ducts.With both types of connection, there is a circular undrilled flangewhich can be used for either screw or rivet fixing, by others.A sealing strip should preferably be fitted first.A spigot is provided for direct connection to spiral or flexiblecircular ducts.The spigot diameter accepts standard circular duct sizes (see table page 4).
Sheet metal flange
Sheet metal flange
A fixed nozzle type DUK-F can be mounted on a stub duct ordirectly on the duct side.An adjustable jet nozzle type DUK-V can be inserted into anexisting connecting spigot up to a depth of dimension X andthen screw fixed to the spigot, alternatively it can be screw fixedto the wall. To hide the screws, a cover ring with a bayonet twistfixing can be fitted.
DUK-F DUK-V
Size D2 No. A N No. X(mm) holes (mm) (mm) holes (mm)
100 115 3 115 125 3 30
125 138 3 138 148 3 40
160 201 4 169 179 4 40
200 241 4 220 232,5 4 50
250 291 4 265 277,5 4 50
315 376 8 330 349 6 55
400 461 8 415 432 6 70
6
Fixed nozzle (DUK-F)mounted on a stub duct
Fixed nozzle (DUK-F) Adjustable nozzle (DUK-V)mounted on the side of a duct mounted on wall
Installation · Assembly
Counterpunched hole � 4.5 mmfor raised countersunk self-tappingscrews 4.2 x 16, DIN 7973
Fixed by others
Siz
e
Size
� D2
Adjustable nozzle (DUK-V)mounted on a stub duct
Existing spigot
7
Nomenclature
A in m: Horizontal distance from nozzles to theairstream collision point
B in m: Spacing distance between two nozzles in a rowH in m: Nozzle installation height above occupied zoneH1 in m: Height of collision point of two air streams above
occupied zoneH2 in m: Height of collision point of two air streams above
mounting position of nozzles, for isothermal conditionsL in m: Length of air stream for isothermal conditionsLmax. in m: Max. penetration depth of warm air stream directed
vertically downwards�K in °: Discharge angle for cold air�W in °: Discharge angle for warm airi : Air induction ratio at distance LV· in l/s: Volume flow rateV· in m3/h: Volume flow ratey in m: Air stream deflection due to temperature difference
from isothermal conditionsveff in m/s: Effective air discharge velocity at nozzle
vK in m/s: Air velocity in ductv-L in m/s: Mean air stream velocityv-H1 in m/s: Time average air velocity entering
occupied zone� tZ in K: Temperature difference between supply air and
room air� tL in K: Temperature difference between core and room air
at distance L� tH1 in K: Temperature difference between core,
when entering occupied zone, and room air� pt in Pa: Total pressure dropLWA in dB(A): A-weighted sound power levelLW NC : Noise criteria rating of sound power level spectrumLW NR : LW NR = LW NC + 1.5
LpA, LpNC : A-weighting or NC-rating respectively of room soundpressure levelLpA � LWA – 8 dBLpNC � LW NC – 8 dB
Cold Air Supply
Isothermal Air Supply
Warm Air Supply
Occupied zone
Occupied zone
1.70 m
1.70 m
1.70 m
8
Selection Method
ExampleData given:2 nozzles are to be fitted at a spacing of 20 m (A = 10 m) and at aheight of H = 5 m above the occupied zone, discharging towardseach other.
The hall is very high, so free jet streams can be assumed.For cooling, for each nozzle V· K = 150 l/s with�tK = – 8 K and for heating, V· W = 150 l/s with�tW = + 4 K.
A motorised swivel movement is required for the nozzles. For theheating phase, an air speed of ƒL = 1.0 m/s is assumed.
Solution:Procedure see below.Taking into account the acoustics, a jet nozzle type DUK-V size 200is selected.
Result:Jet nozzles DUK-V, size 200, must be installed horizontally with themotorised movement set such that a swivel angle of 30° upwardsoccurs with cold air and 25° downwards for warm air.
Cold air � �K = 30°
� L = = 11.5 m
� H2 = tan �K · A = 5.8 m� from diagram 1: ƒL = 1.2 m/s� from diagram 2: y = 0.72 m H1 = H + H2 – y = 5 + 5.8 – 0.72 = 10.1 m� from diagram 3: ƒH1 � 0.07 m/s
Warm air � Given: ƒL = 1.0 m/s� from diagram 1: L = 13 m� from diagram 2: y = 0.51 m� �W = sin-1 ((H + y) / L) = 25
from diagram 8 (with axial connection):at V· = 150 l/s LWA = 44 + 3* = 47 dB(A)
LWNC = 37 + 3* = 40 NC� pt = 160 Pa
from diagram 9 (with branch connection):at 150 l/s LWA ≈ 45 to 50 dB(A) + 2 = *47– 52 dB(A)and ‡K = 6 m/s LWNC ≈ 41 to 46 NC
� pt = 130 Pa x 1.2* ≈ 16 Pa
*Corrections from table page 11
Acos �K
Cold Air
�� � K is selected: e.g. � K = 30°
�� L is calculated: L =A
cos � K
�� H2 is calculated: H2 = tan � K · A
�� ƒ L from diagram 1
�� y from diagram 2
Isothermal Air
Horizontal discharge at � = 0°
�� ƒL from diagram 1 (L = A)
Warm Air
�� ƒL is specified: e.g. v-L = 0.3 m/s
�� L from diagram 1
�� y from diagram 2
� H1 is calculated: H1 = H + H2 – y
�� ƒH1 from diagram 3
If ƒH1 differs from set value, procedure must berepeated with revised � K!
� � tH1 from diagram 4:� tH1 = (� tH1/� t Z) · � t Z
�� v-H1 from diagram 3 (H = H1)
If v-H1 deviates from the specified value, � mustbe corrected upwards or downwards. L and H1are changed as a result. Repeat the analysis.
�� � W is calculated:(� W = sin-1 ((H + y) / L)Note: � W + � K = max. 60°Motorised adjustment of the discharge angle on achange of supply air temperature is only possibleup to max. � W + � K = 60°.
�� � t L from diagram 4:� t L = (� t L/� t Z) · � t Z
� K = ... °
L = ... m
H2 = ... m
ƒL = ... m/s
H1 = ... m
ƒH1 = ... m/s
ƒH1 = ... m/s
� tH1 = ... K
� W = ... °
� tL = ... K
ƒL = ... m/s
y = ... m
ƒL = ... m/s
L = ... m
y = ... m
A, H, � tZ Heating, � tZ Cooling, ‡W, ‡K
Volume flow rate ‡Size of jet nozzle DUK-V
If in a line of nozzles the spacing Bbetween the nozzles is < 0.15 · A then ƒL
and � t L must be multiplied by 1.4.
Given:
Preliminary selection from table on page 3:
Note:
9
Aerodynamic Data
1 Core velocity and Throw
V· �m3/h� =V· �l/s� x 3.6
2 Air Stream Deflection
V· �m3/h� =V· �l/s� x 3.6
� t z is + for warm airand – for cold air.
Air stream deflection yis upwards for warm airand downwards for cold air.
Siz
e
Volume flow ‡ in l/s
Air
stre
am d
efle
ctio
n y
in m
Volu
me
flow
‡in
l/s
Distance L in m
Size
10
Aerodynamic Data
veff = 1000 · Aeff
�m/s� veff = 3600 · Aeff
�m/s�V· V·
3 Core Velocity 6 Maximum penetration depth of a warm airstream,discharging vertically downwards
4 Temperature Quotient
Effective Discharge Velocity
V· in l/s, Aeff in m2 V· in m3/h, Aeff in m2
5 Induction
Lmax is the maximum penetration depth to which awarm air stream can penetrate vertically downwardsas a function of temperature difference.
V· �m3/h� =V· �l/s� x 3.6
H1
in m
ƒH1 in m/s
Tem
per
atur
e Q
uotie
nt ∆
t L/∆
t Zor
∆t H
1/∆t
Z
Distance L or (L+H1) in m
Ind
uctio
n i
Distance
Siz
eM
ax.
pen
etra
tion
dep
th L
max
in m
Volume flow ‡ in l/s
Effective AreaSize Aeff in m2
DUK-F DUK-V100 0.00174 0.0019
125 0.00277 0.0031
160 0.00469 0.0050
200 0.00813 0.0085
250 0.01289 0.0135
315 0.02110 0.0225
400 0.03683 0.0385
11
Aerodynamic Data
7 Sound Power and Pressure Drop 9 Sound Power and Pressure Dropfor axial installation DUK-F for branch installation
8 Sound Power and Pressure Dropfor axial installation DUK-V
The diagrams below apply to the installations shown:
Jet nozzles attached to circular duct (axial installation)
Type DUK-F-...
LWA = diagram value – 3 dB(A)�pt = diagram value x 0.9 Pa
Type DUK-V-...
Jet nozzles attached to the side of a common duct(branch installation)
Type DUK-F-...
Type DUK-V-...
(see page 4!)
LW NC =LWA – 6dB
Pre
ssur
e d
rop
∆p
in P
a
Duc
t To
tal P
ress
ure
∆ptin
Pa
Volume flow ‡ in l/s
Pre
ssur
e d
rop
∆p
in P
a
Size
Size
Siz
e
Correction to Diagram 9
Correction to Diagram 8, for swivel angle � = �30°
Size Swivel angle ∆pt
0° 30° 30°DUK-F / DUK-V DUK-V DUK-V
LWA / LWNC LWA / LWNC
100 – 6 – 4 x 1.2
125 – 4 – 2 x 1.2
160 – 2 0 x 1.2
200 0 2 x 1.2
250 2 4 x 1.2
315 4 6 x 1.2
400 6 8 x 1.2
Size 100 125 160 200 250 315 400LWA / LWNC + 3 + 5 + 3 + 3 + 2 + 2 + 1
12
Des
ign
chan
ges
rese
rved
· A
ll rig
hts
rese
rved
© T
RO
X G
mb
H (1
2/20
06)
Order Details
Specification TextJet nozzles type DUK suitable for long throw distances withoptimum acoustic properties, preferably used for heating andcooling in critical areas. The adjustment facility – manual orautomatic via internal or externally mounted electric actuation –allows variation in discharge angle to compensate for changingtemperature differences, adjustment angular range 30° upwardsto 30° downwards. The manually adjustable version can also berotated through 360°.The fixed jet nozzle type DUK-F consists of an aerodynamicallyshaped discharge nozzle deep-drawn in one piece, with fixingholes. Adjustable construction type DUK-V consists of adischarge nozzle with spherical outlet mounted in a housing, a mounting flange and in a circular duct rear connection spigot for direct connection to a circular duct. Also available with
rear-mounted duct connecting element with peripheral flangeand optional spigot or saddle connection with flange for fixing tothe side of rectangular or circular ducts;the rear contour of the saddle connection is profiled to the ductdiameter.
Materials:The discharge nozzle and face cover ring are in aluminium, the mounting for the eyeball is with two plastic rings colourwhite RAL 9010 (Temperature resistant up to max. 50 °C), theconnection element and saddle connection are in galvanisedsheet steel.The surface can be pre-treated and powder coated in white(RAL 9010) or another RAL colour (the spigots remaingalvanised finish).
Order Code These codes do not need to be completed for standard products
/ / / / /
Fixed FAdjustable V
Only with Duct connection element Kconstruction As K plus spigot A“V” Duct connection element R1)
for circular ducting
Not used Statecolour
0 Unfinished
P0 Powder coatedto RAL9010 (GE 50%)3)
P1 Powder coatedto RAL... (GE 80%)3)
DUK - V - K - E1 250
1002)
1252)
160200250315400Size
0 0 P 1 RAL 9002
IEEOEEP
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IEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEOEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEP
IEEEEOEEEEP
TEEEEZEEEEU
Externally mounted rotary actuator
Actuator E1230 V, 50 Hz
Actuator E224 V, 50 Hz
Actuator E324 V, 50 Hz, 2...10 V-
Internally mounted linear actuator
Actuator E4230 V, 50 Hz
Actuator E524 V, 50 Hz
Actuator E624 V, 50 Hz, 0...10 V-
1) Please indicate the onsite duct diameter (ØR) as supplementary text.2) For sizes 100 and 125, construction with actuator not available.3) GE = Gloss level!
Order Example:Make: TROX Type: DUK - V - K - E1 / 250 / P1 / RAL 9002